A high-density 3-dimensional culture model of human glioblastoma for rapid screening of therapeutic resistance.

Glioblastoma is among the most lethal cancers, with no known cure. A multitude of therapeutics are being developed or in clinical trials, but currently there are no ways to predict which patient may benefit the most from which drug. Assays that allow prediction of the tumor's response to anti-cancer drugs may improve clinical decision-making. Here, we present a high-density 3D primary cell culture model for short-term testing from resected glioblastoma tissue that is set up on the day of surgery, established within 7 days and viable for at least 3 weeks. High-density 3D cultures contain tumor and host cells, including microglia, and retain key histopathological characteristics of their parent tumors, including proliferative activity, expression of the marker GFAP, and presence of giant cells. This provides a proof-of-concept that 3D primary cultures may be useful to model tumor heterogeneity. Importantly, we show that high-density 3D cultures can be used to test chemotherapy response within a 2-3-week timeframe and are predictive of patient response to Temozolomide therapy. Thus, primary high-density 3D cultures could be a useful tool for brain cancer research and prediction of therapeutic resistance.

The origins of glioma: E Pluribus Unum?

Malignant glioma is among of the most devastating, and least curable, types of cancer. Since the re-emergence of the cancer stem cell hypothesis, much progress has been made towards elucidating the cellular origin of these tumors. The hypothesis that tumors are hierarchically organized, with a cancer stem cell at the top that shares defining features with somatic stem cells and provides therapeutic refractoriness properties, has put adult stem cells into the limelight as prime suspect for malignant glioma. Much confusion still exists, though, as to the particular cell type and processes that lead to oncogenic transformation. In this review, we will discuss recent developments and novel hypotheses regarding the origin of malignant gliomas, especially glioblastoma. In particular, we argue that glioblastoma is the result of different pathways originating in multiple sources that all ultimately converge in the same disease. Further attention is devoted to potential scenarios leading to transformation of different stem/progenitor cell types of the brain, and the probability and relevance of these scenarios for malignant tumorigenesis.

Evidence for a progenitor cell population in the human pituitary.

The ability to isolate and propagate adult stem/progenitor cells from the human brain opens novel avenues for cell replacement therapy. This will also apply to the pituitary gland, i.e., following tumor induced endocrine deficiency. Herein, we examine autopsy derived pituitaries to unravel a putative stem/progenitor cell population in humans. In tissue sections of the anterior lobe nestin immunoreactive cells co-expressing smooth muscle actin (SMA) were identified in the perivascular space, indicating a pericytic differentiation. Under clonal conditions, this particular cell population generated primary and secondary cell aggregates (spheres). Pituitary cell cultures maintained a stable cell cycle length with a doubling time of 10 days for over eight months. Forskolin treatment induced a prolactin-expressing phenotype in the majority of cell progenies as well as few betaIII-tubulin (Tuj1) expressing cells of putative neuronal lineage. The presence of sphere-forming, nestin-immunoreactive cells and their ability to generate differentiated cell lineages indicates the existence of a progenitor cell population persisting in the adult human pituitary. Further studies are needed to characterize this cell population in more detail and to clarify their potential to initiate neoplastic transformation for example in the cellular pathogenesis of pituitary adenoma.

Valproic acid increases the SMN2 protein level: a well-known drug as a potential therapy for spinal muscular atrophy.

Proximal spinal muscular atrophy (SMA) is a common neuromuscular disorder causing infant death in half of all patients. Homozygous absence of the survival motor neuron gene (SMN1) is the primary cause of SMA, while SMA severity is mainly determined by the number of SMN2 copies. One SMN2 copy produces only about 10% of full-length protein identical to SMN1, whereas the majority of SMN2 transcripts is aberrantly spliced due to a silent mutation within an exonic splicing enhancer in exon 7. However, correct splicing can be restored by over-expression of the SR-like splicing factor Htra2-beta 1. We show that in fibroblast cultures derived from SMA patients treated with therapeutic doses (0.5-500 microM) of valproic acid (VPA), the level of full-length SMN2 mRNA/protein increased 2- to 4-fold. Importantly, this up-regulation of SMN could be most likely attributed to increased levels of Htra2-beta 1 which facilitates the correct splicing of SMN2 RNA as well as to an SMN gene transcription activation. Especially at low VPA concentrations, the restored SMN level depended on the number of SMN2 copies. Moreover, VPA was able to increase SMN protein levels through transcription activation in organotypic hippocampal brain slices from rats. Finally, VPA also increased the expression of further SR proteins, which may have important implications for other disorders affected by alternative splicing. Since VPA is a drug highly successfully used in long-term epilepsy therapy, our findings open the exciting perspective for a first causal therapy of an inherited disease by elevating the SMN2 transcription level and restoring its correct splicing.